FIGURE 7The excess area = hole area - allowable area = 4.00-3.13 = 0.87in^2 (5.613 cm^2 ). Con-
sider that this excess area is removed from the outstanding legs of the angles, at both the
top and the bottom.
- Compute the moment of inertia of the net section
in^4 dm^4
One web plate,/o 3,456 14.384
Four flange angles,/o 35 0.1456
yfy^2 = 4(6.94)(23.17)^2 14,900 62.0184
Two cover plates:
Ay^2 = 2(7.0)(24.50)^2 8,400 34.9634
/of gross section 26,791 111.5123
Deduct 2(0.87)(23.88)^2 for excess area 991 4.12485
/of net section 25,800 107.387- Establish the allowable bending stress
Use the Specification. Thus h/tw = (48.5 - 8)70.375 < 24,000/(22,00O)
0- 5
; /. 22,000 lb/in
2
(151,690.0 kPa). Also, M= flic = 22(25,800)/[24.75(12)] = 1911 ft-kips (2591.3 kN-m).
- 5
- Calculate the horizontal shear flow to be resisted
Here Q of flange = 13.88(23.17) + 7.0(24.50) - 0.87(23.88) = 472 in
3
(7736.1 cm
3
); q =
VQII= 180,000(472)725,800 = 3290 Ib/lin in (576,167.2 N/m).
From a previous calculation procedure, Rds. = 18,040 Ib (80,241.9 N); Rb =
42,440(0.375) - 15,900 Ib (70,723.2 N); s = 15,900/3290 - 4.8 in (121.92 mm), where s =
allowable rivet spacing, in (mm). Therefore, use a 4%-in (120.65-mm) rivet pitch. This
satisfies the requirements of the Specification.
Note: To determine the allowable rivet spacing, divide the horizontal shear flow into
the rivet capacity.
DESIGN OF A WELDED PLATE GIRDER
A plate girder of welded construction is to support the loads shown in Fig. Sa. The dis-
tributed load will be applied to the top flange, thereby offering continuous lateral support.
PlateWeb plateangleCA. of angles